Method and apparatus for proportioning of fuel usage by a fluid fueled apparatus

ABSTRACT

A fluid proportioning system for apportioning fuel usage among several discrete fluid fuel supplies which are used to supply fluid fuel to a single commonly used apparatus. An application for the invention is in a multidwelling unit wherein each unit is heated from a common furnace. Each tenant&#39;s metered gas line is tapped in proportion to the amount of heat necessary to heat their dwelling unit by the adjustment of precision valves, the gas from each line being combined in a manifold. Means are provided to preclude interaction of the individually metered gas lines when the furnace is not consuming gas.

BACKGROUND AND/OR ENVIRONMENT OF THE INVENTION

1. Field of the Invention

The present invention relates to fluid proportioning systems, and moreparticularly to a method and apparatus for apportioning gas usage by agas fueled apparatus among several individually metered gas supplies.

2. Description of the Prior and/or Contemporaneous Art

Many multiunit dwellings employ a single heating system which suppliesheat to each dwelling unit. This is especially the case in large singlefamily dwellings which have been converted to multifamily dwellings.Heretofore, in most cases, the landlord must underwrite the cost ofheating each of the units since the heating units are usually suppliedfrom a single fuel supply, the cost of which is billed directly to thelandlord. This results in a situation where the landlord's expenses aredisproportionately high in the months that heat is needed. Additionally,since tenants customarily pay a flat amount of rent regardless of theamount of heat used, they do not have an interest in conserving heatand, in many instances, this leads to excessive heat consumption.

One method of limiting the expense to the landlord is by installation ofa locked thermostat so that tenants cannot cause a furnace to supply anunreasonable amount of heat. Unfortunately, this does not do anything toreallocate the cost of heating to each individual tenant. Another moreradical approach is to install individual heating units or furnaces ineach dwelling unit. While this solves the problem, the cost in manyinstances is prohibitive. Additionally, because of the inherent heatlosses through furnace chimneys and combustion chambers, a plurality offurnaces having the same heating capacity as one large furnace will havegreater heat losses and therefore will be less efficient.

In many of these multiunit dwellings, each individual tenant has ametered supply of gas provided to the gas range and other similarappliances disposed in the dwelling unit. However, these are entirelyisolated from the metered supply of gas which is supplied to the commonheating furnace. The present invention provides an apparatus and methodfor equitably apportioning the fuel needed to supply a common furnaceamong a plurality of metered fuel supplies, each which is billedindividually to the tenants of a multiunit dwelling.

U.S. Pat. Nos. 1,892,775 and 1,892,776, both issued to Mix et al. onJan. 3, 1933, each teach fluid control apparatuses wherein a pluralityof tenants' metered gas lines are employed to run a laundry stove. Thisapparatus permits selective individual channeling of the tenants'metered gas to the stove for use at any particular time by a singletenant. No means are shown or suggested for the joint use of the laundrystove by all the tenants through simultaneous supply of gas from eachtenant's metered gas line. The Mix patents are the sole referencesuncovered which seek to equitably attribute gas usage to the tenantderiving benefit from such usage.

Other fluid and fuel mixing and proportioning apparatuses are known inthe art for application for diverse purposes. U.S. Pat. No. 3,280,841issued to Deutsch on Oct. 25, 1966 discloses a fluid mixing andproportioning apparatus wherein two fluid inputs are fed throughseparate valve and pressure meter arrangements. These two arrangementsare manifolded together to provide a single output.

U.S. Pat. No. 3,331,392 issued to Davidson et al. on July 18, 1967teaches a gasoline supply manifold wherein a plurality of gasoline linesare individually hooked to a manifold by a plurality of discrete valves,the output of the manifold being supplied to a gasoline engine.

U.S. Pat. No. 3,392,752 issued to Iozzi et al. on July 16, 1968 shows adevice for mixing a plurality of gases wherein the relative proportionof the gases can be adjusted. Individual gas lines are fed through rateof flow gauges to a manifold housing by a plurality of regulatingvalves. After the gas flows through the regulating valves, it is mixedinto a single flow. This invention finds use in mixing gases fromwelding and in medical applications, such applications beingnonanalogous to the purpose and use of the present invention.Additionally, no means are shown or suggested to isolate the various gassupplies from each other when the gas is not being used. While this isnot necessary in a device such as taught by Iozzi, it is necessary in anapplication where the individual gas lines are used for purposes otherthan to supply a manifold and the apparatus connected thereto.

U.S. Pat. No. 3,667,296 issued to Berger on July 18, 1972 shows a fluidproprtioning system wherein gas is supplied through two fluid regulatorshaving input gauges, then to a pair of independent flow meters, and thento a pair of independent valves. The gas is then channeled through amanifold to a single output. No means are shown or suggested to avoidinteraction between the two gas supplies.

Even considering the diverse and mostly nonanalogous art discussedabove, no fluid proportioning system for use with a fluid fueledapparatus and a plurality of discrete fluid supplies wherein thediscrete fluid supplies are isolated from each other so that they may beused to fuel other apparatuses in addition to the common fluid fueledapparatus is shown or suggested.

The present invention overcomes the shortcomings presently manifested insupplying a plurality of dwelling units from a single fluid fueledapparatus by providing a fluid proportioning system which apportionsfuel usage among a plurality of metered fluid fuel supplies, the fluidfuel supplies being isolated from each other when the fluid fueledapparatus is not in use.

SUMMARY OF THE INVENTION

Therefore, a primary object of the present invention is to provide afluid proportioning system for use with a fluid fueled apparatus and aplurality of discrete fluid supplies wherein fluid fuel use can beapportioned between the fluid supplies.

A further object of the present invention is to provide a fluidproportioning system which can be used in conjunction with a gasfurnace.

A still additional object of the present invention is to provide a fluidproportioning system wherein the proportioned fuel supplies are isolatedfrom each other when not employed for common usage.

A still further object of the present invention is to provide a fluidproportioning system suitable for use in multidwelling units whereineach unit of the dwelling shares usage of a common fluid fueledapparatus.

Still another object of the present invention is to provide a gasproportioning system for use with a gas fueled furnace, the common usageof which is shared by a plurality of separate dwelling units, each ofthe dwelling units having an individually metered gas supply, each ofthe metered gas supplies being used to fuel other appliances located inthe dwelling units.

Still another further object of the present invention is to provide amethod of proportioning fuel usage between a plurality of separatedwelling units each supplied by a single fuel consumptive apparatus.

Another further object of the present invention is to provide a fluidfuel proportioning system which is readily adaptable to currentlyexisting gas fueled furnaces.

Another still further object of the present invention is to provide afluid proportioning system which can be installed for use without majormodification to existing heating systems.

Another still additional and further object of the present invention isto provide a fluid proportioning system which can be assembled fromgenerally available components.

Another object is to avoid the need to replace a single furnace in amultidwelling unit with a plurality of furnaces thereby avoiding theattendant increased energy usage.

Another still further additional object of the present invention is toprovide a fluid proportioning system which is simple in design,relatively inexpensive to manufacture, rugged in construction, easy toemploy, and efficient in operation.

These objects, as well as further objects and advantages of the presentinvention, will become readily apparent after reading the ensuingdescription of the nonlimiting illustrative embodiments and viewing ofthe accompanying drawing.

A fluid proportioning system for use with a fluid fueled apparatus and aplurality of discrete fluid supplies according to the principles of thepresent invention comprises a manifold having a plurality of inputs andan output adapted to be in communication with the fluid input of thefluid fueled apparatus; a plurality of fluid pressure measuring andfluid pressure varying means each having an input and an output, theoutputs of each of the plurality of fluid pressure measuring and fluidpressure varying means being in communication with one of the inputs ofthe manifold, each of the fluid pressure measuring and fluid pressurevarying means inputs being in communication with one of the discretefluid supplies; and a plurality of simultaneously operable valve means,each of the valve means being operably connected to and in communicationwith one of the fluid supplies, the plurality of valve means selectivelyisolating the fluid supplies from each other.

BRIEF DESCRIPTION OF THE DRAWING

In order that the present invention may be more fully understood, itwill now be described, by way of example, with reference to theaccompanying FIGURE which is a pictorial and schematic representation ofone embodiment of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Referring now to the FIGURE, there is illustrated therein a fluidproportioning system 10 which incorporates the principles of the presentinvention. The fluid proportioning system 10 is configured for use insupplying a gas furnace, not illustrated, from a main gas supply 12.Although the invention is shown in this particular environment, it isdone merely for purposes of illustration and it is to be understood thatthe present invention may be used in other environments, in conjunctionwith fuels other than gas, and with fuel consumptive apparatuses otherthan gas furnaces. For instance, the teachings of the present inventionare equally applicable to a hot water supply which is provided tomultiple locations from a single hot water heater.

The gas supply 12, which may be from a public utility or a commonstorage tank, is fed to a plurality of gas meters 14, 16, 18, and 20through a pipe or conduit 21. Pipe 21, as well as other pipeshereinafter mentioned, is shown and described as comprising a pluralityof different length sections and a plurality of couplings or fittings.However, this is merely meant to be illustrative and any pipingconfiguration or other means for permitting the communication of theelements of the present invention and specifically for permitting theinputs of the meters 14, 16, 18, and 20 to be in direct communicationwith the gas supply 12 can be employed by one skilled in the art withinthe scope of the invention.

The outputs of the gas meters 14, 16, 18, and 20 are coupled,respectively, to T connectors 22, 24, 26, and 28. These T connectorsprovide first outputs 30, 32, 34, and 36 which are in communication,through pipes 38, 40, 42, and 44, respectively, to whatever appliancesindividual tenants may have in their dwelling unit for their ownexclusive use. For instance, pipe 38 can be connected to a tenant's gasstove and range. Similarly, pipe 40 may be connected to another tenant'sgas stove, gas range, and gas clothes dryer. In a likewise manner, pipes42 and 44 are also connected to appliances which are used solely by asingle dwelling unit. T connectors 22, 24, 26, and 28 each also havesecond outputs 46, 48, 50, and 52, respectively, which are coupledthrough pipes, respectively, 54, 56, 58, and 60 to the inputs of valves,respectively, 62, 64, 66, and 68. The valves 62, 64, 66, and 68 inconjunction with pressure gauges 70, 72, 74, and 76, respectively, arein communication therewith through, respectively, pipes 78, 80, 82, and84, thereby forming, respectively, fluid pressure measuring and fluidpressure varying apparatuses 86, 88, 90, and 92. The valves 62, 64, 66,and 68 are variable between a closed position and a fully openableposition and are preferably of the precision type which are fullycalibrated. The pressure gauges 70, 72, 74, and 76 each measure thepressure, respectively, between pipes 78, 80, 82, and 84 and,respectively, pipes 94, 96, 98, and 100 which are hooked between theoutputs of the pressure gauges 70, 72, 74, and 76, respectively, and aplurality of electrically operated valves 102, 104, 106, and 108.

The outputs of the electrically operated valves 102, 104, 106, and 108,are coupled to a manifold 110, respectively, by pipes 112, 114, 116, and118. The output 120 of the manifold 110 is connected by a pipe 122 to amaster shut off valve 124, the master shut off valve being connected bya pipe 126 to a master pressure gauge 128. The output of the masterpressure gauge 128 is connected through a pipe 130 to a gas fueledfurnace, not illustrated.

The electrically operated valves 102, 104, 106, and 108 are of thesolenoid type and are simultaneously activated by a relay 132 which isoperably coupled to the electrically operated valves 102, 104, 106, and108 and to the control system of the furnace, not illustrated, in thesame manner as a conventional furnace relay is connected to the controlsystem thereof. When a furnace control system of a conventional typesenses, by the thermostat thereof, that the furnace system should beactivated, voltage is applied to a relay which opens a gas valve. Whenthe relay 132 is hooked to the furnace control system, it also will beactivated and will place a selected voltage on the solenoid valves 102,104, 106, and 108 to open these devices thereby permitting the passageof gas therethrough. When the solenoid valves 102, 104, 106, and 108 aredeactivated, they preclude the passage of gas therethrough. The solenoidvalves 102, 104, 106, and 108, as well as the relay 132, may beactivated by readily available 110V AC house current or they can beactivated by a 24V or other low voltage current if such is used in thefurnace control system or if such low voltage is otherwise desirable.

In employing the system 10, the square footage of each of the individualdwelling units associated with gas meters 14, 16, 18, and 20 would becalculated to determine the number of BTU's of heat needed to heat theseunits. The method of calculating such quantities of heat are well knownin the art and factors such as insulation, exposure, outside walls, andwindows can be taken into consideration. However, all these factorsexcept for square footage are assumed to be equal for purposes ofsimplicity of illustration. The manner in which the valves 62, 64, 66,and 68 are adjusted to apportion gas usage can be illustrated byassuming that the dwelling units associated with meters 14 and 16 are ofequal size and the dwelling units associated with meters 18 and 20 areequal in size to each other, the dwelling units associated with meters14 and 16 being one half the size of the dwelling units associated withmeters 18 and 20. In a conventional installation, gas pressure isapproximately twenty-five to thirty pounds per square inch. For purposesof illustration, it is assumed that the pressure is thirty pounds persquare inch. Using the example above, valves 62 and 64 would be adjustedso that pressure gauges 70 and 72 had a pressure reading of five poundsper square inch with valves 66 and 68 being adjusted so that gauges 74and 76 show a pressure of ten pounds per square inch. The total pressuretherefore would be thirty pounds per square inch at manifold output 120,as read by gauge 128, but the gas meters 14, 16, 18, and 20 would onlybe metering gas usage in proportion to gas consumption in the associateddwelling unit.

As another example, if the dwellings associated with meters 14, 16, and18 were of equal size and if the dwelling unit associated with meter 20was twice as large as dwellings associated with meters 14, 16, and 18,the valves 62, 64, and 66 would be adjusted so that the pressure gauges70, 72, and 74 would read a pressure of six pounds per square inch,valve 68 being adjusted to indicate a pressure of twelve pounds persquare inch at pressure gauge 76. Similarly, if each dwelling unit wasequal in size and if there were four dwelling units, each valve 62, 64,66, and 68 would be adjusted to permit a pressure of seven and one halfpsi at pressure gauges 70, 72, 74, and 76. Thusly, it can be seen thatthe individual owners of the dwelling units are contributing gas for therunning of the common furnace in proportion to the amount of heatnecessary to heat their dwelling unit. As a result, an equitable systemis provided with each tenant paying their proportional share of the costof purchasing gas thereby alleviating the landlord of this oppressiveresponsibility.

Of course, the more precisely the calculation is made to determine thequantity of heat necessary to heat a dwelling unit, the more equitablesuch proportioning will be.

The electrically operated valves 102, 104, 106, and 108 are provided topreclude interaction of the metered gas supplies of each separatedwelling unit when the furnace is not in use. If the valves 102, 104,106, and 108 were not provided, and the furnace was not in use, if oneof the tenants was to use gas from gas supplies 38, 40, 42, or 44, hecould draw gas through the manifold 110 from the other tenants' meteredgas supplies. However, since the electrically operated valves 102, 104,106, and 108 are provided, and are in a closed position unless thefurnace is operating, if the individual dwelling units use gas from thegas supplies 38, 40, 42, and 44, they will only draw gas through theirown gas meters.

It should be apparent that the proportioning valves 62, 64, 66, and 68;the pressure gauges 70, 72, 74, and 76; and the electrically operatedvalves 102, 104, 106, and 108 can be variously interchanged in position,respectively, between the gas meters 14, 16, 18, and 20 and the manifoldinputs 112, 114, 116, and 118. Such juxtaposition is considered to bewell within the skill of one of ordinary skill in the art within thescope of the present invention. Similarly, the valves 62, 64, 66, and 68can be provided as discrete components relative to the pressure gauges70, 72, 74, and 76 or, as illustrated, can be embodied by a single unitwhich performs both pressure varying and pressure measuring functions.As an alternative within the scope of the present invention, fluidpressure measuring and fluid pressure varying apparatuses 86, 88, 90,and 92 can comprise calibrated mechanical gas control valves of the typeused in gas ranges and ovens.

The master valve 124 is provided to permit shutoff of the output 120 ofthe manifold 110 as desired for servicing of the furnace or in othersituations where such a condition is desirable. The master pressuregauge 128 is provided to make sure that the maximum pressure supplied tothe furnace does not exceed the amount which it may accept. As in theexamples above, such a pressure would be thirty pounds per square inch.

In order to preclude tenant tampering, the valves 62, 64, 66, and 68should be lockable and, along with the pressure gauges 70, 72, 74, and76 may be disposed in a single locked box to which the tenants are notpermitted access.

Alternately, the valves and pressure gauges used to proportion the gasfrom each individual tenant's metered gas supply may be remotelyvariable. For instance, an electrically operated remotely calibratedvalve means with a remote readout and adjustment located in eachdwelling unit may be employed. The remote valve controls alsonecessarily would be locked, if desired, and the adjustments of theproportioning could be remotely accomplished. This might be ofparticular convenience where a single dwelling unit is frequently emptyand, when the heat supply is turned off to such a vacant unit, the gassupply which is associated with the unit can also be turned off.

Although the system 10 hereinbefore described has been described asaccommodating four dwelling units, of course, more or less dwellingunits can be accommodated by the provision of additional manifoldinputs, electrically operated valves, proportional valves, and pressuregauges. It also should be realized that although conventional pipe andpipe connections are shown, other specially manufactured or conventionaldevices or apparatuses for coupling the components of the presentinvention together may be employed using the skill of one of ordinaryskill in the art placing such modifications within the scope of thepresent invention.

The teachings of the present invention are also applicable toinstallations wherein more than one commonly shared appliance isemployed. For instance, if all the dwelling units involved use a singlegas furnace and a single gas hot water heater, the output of themanifold can be connected to both of these appliances, consumption ofthe furnace being determined as hereinbefore described and acorrectional factor being introduced as to estimated hot water use byeach dwelling unit. Although this is a less precise calculation than thequantity of heat needed to heat a dwelling unit, reasonableproportioning of hot water usage can be determined based on the numberof people occupying each dwelling unit.

It should be understood that various changes in the details, materials,arrangements of parts, and operational conditions which have been hereindescribed and illustrated in order to explain the nature of theinvention may be made by those skilled in the art within the principlesand scope of the invention.

Having thus set forth the nature of the invention, What is claimedis:
 1. a fluid proportioning system for use with a fluid fueledapparatus and a plurality of discrete fluid supplies comprising:amanifold having a plurality of inputs and an output adapted to be incommunication with the fluid input of said fluid fueled apparatus; aplurality of fluid pressure measuring and fluid pressure varying meanseach having an input and an output, said outputs of each of saidplurality of fluid pressure varying means being in communication withone of said inputs of said manifold, each of said fluid pressuremeasuring and fluid pressure varying means inputs being in communicationwith one of said discrete fluid supplies; and a plurality ofsimultaneously operable valve means, each of said valve means beingoperably connected to and in communication with one of said fluidsupplies, said plurality of valve means being either simultaneouslyopened or simultaneously closed for selectively isolating said fluidsupplies from each other.
 2. A fluid proportioning system in accordancewith claim 1, wherein each of said simultaneously operable valve meanscomprises an electrically controlled valve and means for selectivelysimultaneously powering said electrically controlled valves.
 3. A fluidproportioning system in accordance with claim 2, wherein said selectivesimultaneous powering means is operably connected to said fluid fueledapparatus, demand of said fluid fueled apparatus for fuel opening saidelectrically controlled valves, cessation of said demand closing saidvalves.
 4. A fluid proportioning system in accordance with claim 3,wherein said electrically controlled valves are of the solenoid type,said selective simultaneous powering means comprising a relay connectedto said valves for powering the same upon a signal from said fluidfueled apparatus.
 5. A fluid proportioning system in accordance withclaim 1, wherein each of said plurality of fluid pressure measuring andfluid pressure varying means comprises a pressure gauge and a valve, theopening in said valve being variable between a closed position and afully operable position.
 6. A fluid proportioning system in accordancewith claim 5, wherein each of said pressure gauges and each of saidvalves, and each of said simultaneously operable valve means each havean input and an output, the outputs of each of said valves being incommunication with the input of the associated said pressure gauge, theinputs of each of said valves being in communication with one of saiddiscrete fluid supplies, the outputs of each of said pressure gaugesbeing in communication with one of the inputs of said simultaneouslyoperable valve means, the outputs of each of said simultaneouslyoperable valve means being in communication with one of said inputs ofsaid manifold.
 7. A fluid proportioning system in accordance with claim1, further comprising master shut off valve means operably interposedbetween said output of said manifold and said fluid input of said fluidfueled apparatus.
 8. A fluid proportioning system in accordance withclaim 7, further comprising master fluid pressure measuring meansoperably interposed between said master shut off valve means and thefluid input of said fluid fueled apparatus.
 9. A gas proportioningsystem for use with a gas fueled appliance, the common usage of which isshared by a plurality of separate dwelling units, each of said dwellingunits having an individual gas supply, said system comprising:a manifoldhaving a plurality of inputs and an output adapted to be incommunication with the gas input of said gas fueled appliance; aplurality of gas pressure measuring and gas pressure varying means eachhaving an input and an output, said outputs of each of said plurality ofgas pressure measuring and gas pressure varying means being incommunication with one of said inputs of said manifold, each of said gaspressure measuring and gas pressure varying means inputs being incommunication with one of said individual gas supplies; and a pluralityof simultaneously operable valve means, each of said valve means beingoperably connected to and in communication with one of said individualgas supplies, said plurality of valve means being either simultaneouslyopened or simultaneously closed for selectively isolating saidindividual gas supplies from each other; one of said gas pressuremeasuring and gas pressure varying means being thereby associated witheach of said dwelling units, the gas pressure of each of said gaspressure measuring and gas pressure varying means being independentlysetable to a pressure corresponding to the character of said associateddwelling unit according to a preselected formula.
 10. A gasproportioning system in accordance with claim 9, wherein each of saidsimultaneously operable valve means comprises an electrically controlledvalve and means for selectively simultaneously powering saidelectrically controlled valve.
 11. A gas proportioning system inaccordance with claim 10, wherein said selective simultaneous poweringmeans is operably connected to the control system of said gas fueledappliance, activation of said gas fueled appliance by said controlsystem thereof opening said electrically controlled valves, deactivationof said gas fueled appliance by said control system thereof closing saidelectrically controlled valves.
 12. A gas proportioning system inaccordance with claim 11, wherein said electrically controlled valvesare of the solenoid type, said selective simultaneous powering meanscomprising a relay connected to said valves for powering the same upon asignal from said gas fueled appliance control system.
 13. A gasproportioning system in accordance with claim 9, wherein each of saidplurality of gas pressure measuring and said gas pressure varying meanscomprises a pressure gauge and a valve.
 14. A gas proportioning systemin accordance with claim 13, wherein each of said pressure gauges andeach of said valves and each of said simultaneously operable valve meanseach have an input and an output, the outputs of each of said valvesbeing in communication with the input of the associated said pressuregauge, the inputs of each of said valves being in communication with oneof said individual gas supplies, the outputs of each of said pressuregauges being in communication with one of the inputs of saidsimultaneously operable valve means, the outputs of each of saidsimultaneously operable valve means being in communication with one ofsaid inputs of said manifold.
 15. A gas proportioning system inaccordance with claim 9, further comprising master shut off valve meansoperably interposed between said output of said manifold and said gasinput of said gas fueled apparatus.
 16. A gas proportioning system inaccordance with claim 15, further comprising master fluid pressuremeasuring means operably interposed between said master shut off valvemeans and the fluid input of said gas fueled apparatus.
 17. A gasproportioning system in accordance with claim 9, wherein each of saidgas pressure measuring and gas pressure varying means comprises anelectrically operated remotely calibrated valve means.
 18. A gasproportioning system in accordance with claim 17, wherein each of saidelectrically operated remotely calibrated valve means are remotelyoperable from the associated dwelling unit.
 19. A gas proportioningsystem in accordance with claim 18, wherein said gas fueled appliancecomprises a gas furnace ducted to each of said dwelling units.